Productive and nutritional characteristics of Piatã-grass in integrated systems

Barros, Jeskarlândia Silva; Castro, Laura Cristina Souza; Silva, Fabiane de Lima; Alves, Fabiana Villa; Almeida, Roberto Giolo de; Santos, Divaney Mamédio dos; Loures, Daniele Rebouças Santana

doi:10.1590/S1519-99402018000200001

SUMMARY

This study aimed to evaluate the pasture productive and nutritional characteristics of Brachiaria brizantha cv. BRS Piatã in integrated systems with different densities of trees. Considering as plot the systems: integrated crop-livestock-forest with rows of trees (eucalyptus) spaced at 14 m and 357 trees ha^-1 (ICLF-14m), ICLF with rows of trees spaced at 22 m and 227 trees ha^-1 (ICLF-22m) and the integrated crop-livestock (ICL) with five remaining native trees ha^-1; period of the year as subplots, and sampling points as subsubplots (A, B C, D, and E) arranged perpendicular to trees alleys. It was evaluated the production of forage and leaf blade dry mass, leaf:stem ratio, soil coverage, radiation photosynthetically active interception, canopy height, crude protein (CP), neutral detergent fiber (NDF), in vitro digestibility of organic matter (IVDOM) of the leaf blade, and stem associated with the leaf sheath. There was a significant difference (P<0.05) for all variables due to the month within the integrated systems. Mainly in January and March, showing the forage and leaf blade dry mass reduction due to a higher trees density. System with higher trees density showed the lowest soil coverage and canopy height sampling points A and E in ICLF-22m showed lower forage and leaf blade dry mass production and soil coverage. The system with higher trees density showed lower value of NDF of the leaf blade, and higher CP contents. The IVDOM of the leaf blade was higher in ICLF systems. For the evaluated parameters the best results were for the ICLF-22m.

Key words:
agroforestry; Brachiaria brizantha; crude protein; shading; tropical pasture

RESUMO

Objetivou-se com este estudo avaliar as características produtivas e nutricionais da pastagem de Brachiaria brizantha cv. BRS Piatã em sistemas integrados com diferentes densidades de árvores. Considerando como trama os sistemas: planta integrada-pecuária com fileiras de árvores (eucalipto) espaçadas a 14 m e 357 árvores ha-1 (ICLF-14m), ICLF com fileiras de árvores espaçadas a 22 m e 227 árvores ha^-1 (ICLF-22m) e o cultivo-pecuária integrado (ICL) com cinco árvores nativas restantes ha^-1; período do ano como subparcelas e pontos de amostragem como sub-sub-parcelas (A, B C, D e E) dispostas perpendicularmente às vielas das árvores. Foi avaliada a produção de massa seca de lâmina e folha, relação folha: caule, cobertura do solo, intercepção fotossintética de radiação, altura do dossel, proteína bruta (PB), fibra de detergente neutro (FDN), digestibilidade in vitro de matéria orgânica (DIVMO) da lâmina da folha e haste associado com a bainha da folha. Houve uma diferença significativa (P <0,05) para todas as variáveis devido ao mês dentro dos sistemas integrados. Principalmente em janeiro e março, mostrando a redução da massa seca da forragem e das folhas devido a uma maior densidade de árvores. O sistema com maior densidade de árvores mostrou a menor cobertura de solo e a altura do dossel. Os pontos de amostragem A e E em ICLF-22m apresentaram menor produção de massa seca e lâmina foliar e cobertura do solo. O sistema com maior densidade de árvores apresentou menor valor de FDN da lâmina da folha e maior índice de PB. A DIVMO da lâmina da folha foi maior nos sistemas ICLF. Dos parâmetros avaliados os melhores resultados foram para o sistema ICLF-22m.

Palavras-chave:
agroflorestal; Brachiaria brizantha; proteína bruta; sombreamento; pastagem tropical

INTRODUCTION

The integrated crop-livestock-forest system, known as agroforestry system, is a planned agroforestry practice, aiming to take advantage of each interactions, and have benefits without damage to both parties (PACIULLO et al., 2011PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011.).

Herbaceous forage growth on shaded environments, present variations influencing productivity dynamics and numerous forage characteristics (GARCIA et al., 2010GARCIA, R.; TONNUCCI, R.G.; GOBBI, K.F. Silvipastoris: uma integração pasto, árvore e animal. In: OLIVEIRA NETO, S.N. VALE, A.B.; NACIF, A.P.; VILAR, M.B.; ASSIS, J.B. (Eds). Sistema agrossilvipastoril: integração lavoura, pecuária e floresta. Viçosa, MG: Sociedade de Investigação Florestal, 2010. 189.p), provided by changes in quantity and quality of light available in the understory (SOARES et al., 2009SOARES, A.B.; SARTOR, L.R.; ADAMI, P.F.; VARELLA, A.C.; FONSECA, L.; MEZZALIRA, J.C. Influence of luminosity on the behavior of eleven perennial summer forage species. Revista Brasileira de Zootecnia, v.38, p.443-451, 2009.), thus influencing the nutritional value and productivity dynamics.

Depending on the forage species and shading level, there is usually a positive influence on the nutritive value of grasses such as higher crude protein levels, cell wall content reduction, and digestibility increase (PACIULLO et al., 2007PACIULLO, DSC.; CARVALHO, C.A.B.; AROEIRA, L.J.M.; MORENZ, M.J.F.; LOPES, F.C.F.; ROSSIELLO, R.O.P. Morphophysiology and nutritive value of signalgrass under natural shading and full sunlight. Pesquisa Agropecuária Brasileira, v.42, p.573-579, 2007.). However, there is a trend to produce less forage, mainly due to the lower light radiation in the understory (ALMEIDA et al., 2012ALMEIDA, R.G.; BARBOSA, R.A.; ZIMMER. A.H; KICHEL, AN. Forrageiras em sistemas de produção de bovinos em integração. In: BUNGENSTAB, D.J. Sistemas de integração lavoura-pecuária-floresta: a produção sustentável. 2.ed. Brasília, DF: EMBRAPA, 2012. p.88-94.).

The forage growth in the integrated system depends on its shading tolerance and shade percentage imposed to the understory. Shading caused by tree species may impair or favor forage growth, depending on the degree of shading and the amount of solar radiation that is intercepted by the tree canopy, as it restricts the interception potential of the forage that responds for this situation with adaptation and acclimatization phenotypical (OLIVEIRA et al., 2014OLIVEIRA, C.C.; VILLELA, D.S.; ALMEIDA, R.G.; ALVES, F.V.; NETO BEHLING, A.; MARTINS, P.G.M.A. Performance of Nellore heifers, forage mass, and structural and nutritional characteristics of Brachiaria brizantha grass in integrated production systems. Tropical Animal Health and Production, v.46, p.167-172, 2014.; PACIULLO et al., 2011PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011.; GOBBI et al., 2009GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.G.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Morphological and structural characteristics and productivity of Brachiaria grass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.38, p.1645-1654, 2009.). In this context, it is worth highlighting the Brachiaria brizantha (Syn. Urochloa brizantha) cv. BRS Piatã by presenting adaptation to shading, high foliar growth rate, good nutritional value (VALLE et al., 2007VALLE, C.B.; EUCLIDES, V.P.B.; VALÉRIO, J.R.; MACEDO, M.C.M.; FERNANDES, CD.; DIAS FILHO, M.B. Brachiaria brizantha cv. Piatã: uma forrageira para diversificação de pastagens tropicais. Seed News, v.11, n.2, p.28-30, 2007.), an average productivity of 11.5t ha^-1 of dry matter in conventional grazing system (DIM et al., 2015DIM, V.P.; ALEXANDRINO, E.; SANTOS, A.C.; MENDES, R.S.; SILVA, D.P. Agronomic characteristics, structural and chemical characteristics of grass in Piata stocking with intermittent rest periods vary depending on the sward height. Revista Brasileira de Saúde e Produção Animal [online], v.16, n.1, p.10-22, 2015.).

In this regard, this study aimed to evaluate the productive and nutritional characteristics of Piatã-grass in agroforestry system.

MATERIAL AND METHODS

The experiment was performed at Campo Grande – MS, Brazil (Latitude 20° 27’ South; Longitude 54° 37’ West; Altitude of 530 m). The experimental area consists of red Latosol (SANTOS et al., 2006SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de; OLIVEIRA, J.B. de; COELHO, M.R.; LUMBRERAS, J.F.; CUNHA, T.J.F. (Ed.). Sistema brasileiro de classificação de solos. 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306p.), characterized by clayey, acid pH, low base saturation, high aluminum concentration, and low phosphorus content.

The climate, according to Köeppen (1948) classification, belongs to the transition range between Cfa and Aw tropical rain; and the average annual rainfall is 1,560 mm. During the experiment, climate data were collected at the weather station of Embrapa Beef Cattle, located at 3 km of the experimental area, from September 2014, corresponding to the end of dry season, to February 2015, corresponding to the beginning of the wet season (Table 1).

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Table 1
Mean values of maximum temperature (Tmax), minimum temperature (Tmin), relative humidity (RH), and rainfall from 2014 to 2015

This study evaluated the pasture of April 2014, with Brachiaria brizantha cv. BRS Piatã [Syn. Urochloa brizantha], in integrated systems established in 2008/2009, which is the agroforestry system (ICLF) with hybrid eucalyptus seedlings “urograndis” (Eucalyptus urophylla × Eucalyptus grandis, clone H 13) in two arrangements of trees: one in simple lines, spaced 14 m between the lines, 2 m between plants, and density of 357 trees ha^-1 (ICLF-14m); another with eucalyptus seedlings in simple lines, spaced 22 m between the lines, 2 m between plants, and density of 227 trees ha^-1 (ICLF-22m), and agropastoral system (ICL, control) with five remaining native trees ha^-1. Each system consists of four paddocks of 1.5 ha^-1 area, in a total of 12 experimental paddocks.

The experimental design for plant component was performed in split-split-plot randomized blocks design with four replications. Plots treatments consisted of integrated systems ICLF-14m, ICLF-22m, and ICL. Subplots treatments correspond to the time of the year (spring and summer), and the split-plots treatments corresponded to the sampling places: A, B, C, D and E

Forage evaluations were performed in two perpendicular transects to trees rows per plot. In each transect, five equidistant points were delimited (A, B, C, D and E), where A and E were located at 2 m from trees trunks, and C correspond to the intermediate position, totalizing ten samples per plot.

At each point of 1.0 × 1.0 m, the canopy height measure was performed from the distances average of the plant base to the leaves curvature, measured with rulers graduated in centimeters in each point, within each plot; the soil coverage was visually evaluated and determined in percentage, then the forage was cut at surface level with a brush cutters. Two transects randomly arranged in the pasture were considered for system with native remaining trees. Cut material in 49-day intervals was taken to the laboratory, and weighed and divided into sub-samples.

Photosynthetically active radiation (PAR) readings were performed in each sampling point, by a ceptometer model PAR-80, Decagon Devices. A reading in both canopy top and ground level was performed at each point. Samples were separated in leaves (only foliar blade), stems (leaf sheath and stem) and aged material (leaves or stems with more than 50% of the dry area), then taken to drying in forced air chamber at 55°C, until reaching constant mass in 72 hours. After pre-drying, subsamples were ground separately in “Thomas Wiley” mill grinder, model 4, using 1 mm mesh sieve, identified and packaged in glass pot for chemicalbromatological analysis.

Forage productivity and different components as leaf and stem of living material were estimated based on dry matter. By dry matter data of leaf:stem fraction, it was calculated the leaf:stem ratio (L/S ratio), according to the methodology described by Mannetje (1978MANNETJE, L.T. Measurement of grassland vegetation and animal production. Aberystwyth: CAB, 1978. 260 p. (CAB Bulettin, 52).).

Bromatological composition, crude protein (CP), neutral detergent fiber (NDF), and in vitro organic matter digestibility (IVDOM), was evaluated from a representative sample, by means of near infrared reflectance spectroscopy (NIRS), according to Marten et al. (1985MARTEN, G.C.; SHENK, J.S.; BARTON II, F.E. Near infrared reflectance spectroscopy (NIRS): analysis quality. Washington: USDA, 1985. p.110. (Agriculture handbook, 643).). Statistical analyzes were submitted to variance analysis, and the averages were submitted to Scott-Knott test with 5% probability, by using the SAS - Statistical Analysis System, version 8.0 (2002).

RESULTS AND DISCUSSION

There was a significant difference between the periods of the year and the integrated systems for all variables (Table 2).

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Table 2
Total forage dry matter (TFDM), leaf blade dry matter (LDM), leaf:stem ratio (L/S ratio), soil coverage (SC), photosynthetically active radiation (PAR), and pasture height according to the period of the year, in three integrated systems

March presented higher production of TFDM and LDM (kg ha^-1) in all studied systems; however, ICL showed the highest total forage production of 2,867 kg ha^-1 and leaf blade of 1,091 kg ha^-1. However, November presented lower forage production of 839 kg ha^-1 for THDM variable of ICLF-22m. September and November presented lower production of LDM in ICLF-22 and 14m, assuming an average production around 216 and 99 kg ha^-1, respectively.

The increment in the total forage dry matter and in the leaf blade can be associated with less trees competition for light, nutrients, and water, according to Martuscello et al. (2009MARTUSCELLO, J.A.; JANK, L.; GONTIJO NETO, M.M.; LAURA, V.A.; CUNHA, D.N.F.V. Genus Brachiaria grass yields under different shade levels. Revista Brasileira de Zootecnia, v.38, p.1183-1190, 2009.), environments with shading level increased linearly reduces the dry matter production of Brachiaria decumbens and B. brizantha.

The leaf:stem ratio (L/S ratio) for ICL was higher in November and January with average of 2.45. ICLF-14m showed a higher leaf:stem ratio in November, January and March. ICLF-22m showed the highest ratio in November with 2.50. It is probably the highest leaf:stem ratio presented in the months aforementioned, because of the rainy season, and favorable environmental resources for plant development.

Green leaves show high crude protein content, as well as digestibility and consumption, which is an advantage for grazing since the leaves have better nutritional value. According to Araújo et al. (2013)ARAUJO, R.P.; ALMEIDA, J.C.C.; ARAÚJO, S.A.C.; RIBEIRO, E.T.; PÁDUA, F.T.; CARVALHO, C.A.B.; BONAPARTE, T.P.; DEMINICIS, B.B.; LISTA, F.N. production and chemical composition of brachiaria decumbens cv. Basilisk in silvipastoral system under different spacing with eucalyptus urophylla s.t. blake. Revista Brasileira de Agropecuária Sustentável, v.3, p.90-98, 2013. the leaf:stem ratio is a variable influenced by the incident radiation level, and may result in stem etiolation reducing the leaf:stem ratio, or in a contrary way, may result in leaf size increase, increasing the leaf:stem ratio.

According to Gobbi et al. (2009GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.G.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Morphological and structural characteristics and productivity of Brachiaria grass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.38, p.1645-1654, 2009.), shaded grasses provide structural, adaptive, and competitive changes in the leaves to capture more light and invest in higher assimilate proportion. These authors also report that the increase of shoot: root ratio, elongation of stems and leaf blade, reduction of branching and tillering, the increase of specific leaf area and changes in leaf: stem ratio are morphological alterations of grasses under shading conditions.

Therefore, in this study, we observed that the denser arrangement of trees reduced the leaf: stem ratio especially in September, November and January.

The highest soil coverage percentage (SC) was observed in January for ICL and ICLF-22m, 83% and 75%, respectively. However, ICLF-14m presented the highest soil coverage percentage in March, even though, was lower than the other systems, 46%. The soil coverage variable response in this study is an indication that the wider spacing of eucalyptus favored for higher soil coverage, since areas with higher trees density present less incident radiation intercepted by the canopy.

The soil coverage, provided by Piatãgrass is associated with the pasture productive capacity, which present less space of uncovered areas. On the other hand, the soil coverage is an important opportunity to prevent the soil surface from water runoff, and hence erosion (GALHARTE & CRESTANA, 2010GALHARTE, C.A.; CRESTANA, S. The assessment of the environmental impact of agriculture-animal husbandry integration: Environmental conservation aspect in ‘Cerrado’. Revista Brasileira de Engenharia Agrícola e Ambiental, v.14, p.1202-1209, 2010.). Thus, the weed reduction is guaranteed, improving soil quality, and increasing the forage species productivity.

The highest incidence of photosynthetically active radiation (PAR) occurred in ICL, in November and March, with an average of 1,609 μmol m^{- 2} s^-1. ICLF-22m showed the highest value in March, 1,247 μmol m^-2 s^-1. However, this has not differ statistically from values presented by ICLF-14m, for all analyzed months. It was expected that ICLF-14m presented lower solar radiation on canopy in September and November, due to their lower leaf:stem ratio in the same period, where PAR intercepted and absorbed by the leaves, by means of chloroplast pigments would be different between systems.

Biomass productivity of a culture is related, among other factors, to the radiation photosynthetically active fraction absorbed by canopy. According to Martins et al. (2010MARTINS, J.R.; ALVARENGA, A.A.; CASTRO, E.M.; SILVA, A.P.; ALVES, E. Pigments content and Alfavaca-cravo chloroplast structure cultivate under colored nets. Ciência Rural, v.40, p.64-69, 2010.), chloroplastid pigments contents, chlorophyll, and carotenoids are related to the photosynthetic efficiency of plants, therefore, the radiation quantity ratio incident on the cultivation environment provides an adjustment in the plants photosynthetic system, which is essential for the absorption efficiency and energy transfer for photosynthetic processes.

The radiation quantity reduction incident on canopy of cultivated forage in understory can interfere with the shoot development and root growth, decreasing them. The absorbed PAR represent the efficiency in which the plant absorbs the incident photosynthetically active radiation (PAR_i) in the canopy, which is variable over the cycle, and in the growth and development conditions of plants (FONTANA et al., 2012FONTANA, D.C.; ALVES, G.M.A.; ROBERTI, O.L.L.M.; GERHARDT, A. Estimation of the absorbed photosynthetically active radiation by the soybean crop through modis sensor data. Bragantia, v.71, p.563-571, 2012.).

In the case of pasture height variable, the highest values were observed in ICLF-22m and ICLF-14m, in March, as well as the highest average height observed for ICL was 42.5 cm in January and March. Piatã-grass growth was favored by wet conditions provided by treetop, by the highest PAR values recorded in March, and the weather condition presented by the month (Table 1).

Plant growth depends on the availability of favorable environmental factors, and assimilates partitioning between shoot and root. In case of cultivated pastures when shaded, it present strategies in response to less light, in order to reach a higher extract and go out of the shadow, starting the stem elongation process (SILVA et al., 2009SILVA, S.C da.; BUENO, A.A.O.; CARNEVALLI, R.A.; UBELE, M.C.; BUENO, F.O.; HODGSON, J.; MATTHEW, C.; ARNOLD, G.C.; MORAIS, J.P.G. Swards structural charateristic and herbage accumulation of Panicum maxinum cv. Mombaça subjected to rotational stocking managements. Scientia Agrícola, v.66, p.8-19, 2009.), and reducing the tillers population density (SBRISSIA & SILVA, 2008SBRISSIA, A.F.; SILVA, S.C. da. Tiller size/density compensation in Marandu palisadegrass swards. Revista Brasileira de Zootecnia, v.37, p.35-47, 2008.).

The higher stems length and petioles can represent a plant effort to increase its access to the light available to the canopy (PERI et al., 2007PERI, P.L.; LUCAS, R.J.; MOOT, D.J. Dry matter production, morphology and nutritive value of Dactylis glomerata growing under different light regimes. Agroforestry Systems, v.70, p.63-79, 2007.). However, pastures under shading show lower forage dry matter, compensating it showing higher crude protein content and in vitro digestibility of organic matter (ALMEIDA et al., 2012ALMEIDA, R.G.; BARBOSA, R.A.; ZIMMER. A.H; KICHEL, AN. Forrageiras em sistemas de produção de bovinos em integração. In: BUNGENSTAB, D.J. Sistemas de integração lavoura-pecuária-floresta: a produção sustentável. 2.ed. Brasília, DF: EMBRAPA, 2012. p.88-94.).

There was a significant difference between the periods of the year and integrated systems on the parameters related to forage quality shown in Table 3.

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Table 3
Crude protein (CP), neutral detergent fiber (NDF), and in vitro digestibility of organic matter (IVDOM) of leafe blade and stem+sheat, according to the period of year, in three integrated systems

The higher crude protein content of the leaf blade was observed in March, 16.65% in ICLF-14m. However, the same system had the lowest percentage in January, 11.5% for the same variable. Probably, the best response can be related to the favorable microclimate that trees provided in the understory, promoting moisture retention and nutrient recycling; however, the particularity presented in January, can be explained by the influence of the higher radiation photosynthetically active interception in the canopy (Table 2).

According to some authors (GOBBI et al., 2010GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Nutritive value of signalgrass and forage peanut submitted to shading. Archivos de Zootecnia, v. 59, p. 379-390, 2010.; SOUSA et al., 2010SOUSA, L.F.; MAURÍCIO, R.M.; MOREIRA, G.R.; GONÇALVES, L.C.; BORGES, I.; PEREIRA, L.G.R. Nutritional evaluation of Braquiarão grass in association with Aroeira trees in a silvopastoral system. Agroforestry Systems, v.79, n.2, p.189-199, 2010.; PACIULLO et al., 2011PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011.) in areas under trees influence, grasses have higher crude protein content than in full sun, being attributed to the higher nitrogen (N) recycling and soil moisture.

Fiber content in neutral detergent fiber (NDF) of leaf blade of Piatã-grass showed no significant difference throughout the year in ICL, except for the highest value obtained in January, 76.75%. This value is consistent with the results shown by ICLF-22m, in the same observation period. The lower NDF content was observed in ICLF- 14m, in September. Dim et al. (2015DIM, V.P.; ALEXANDRINO, E.; SANTOS, A.C.; MENDES, R.S.; SILVA, D.P. Agronomic characteristics, structural and chemical characteristics of grass in Piata stocking with intermittent rest periods vary depending on the sward height. Revista Brasileira de Saúde e Produção Animal [online], v.16, n.1, p.10-22, 2015.) working with Piatã-grass, observed that the higher the pasture height, the higher the NDF content, corroborating with the results analyzed in ICLF-22m.

For in vitro digestibility of organic matter of leaf blade, the lowest percentages were observed in January, in ICL and ICLF-22m, which have not differed from each other, and ICLF-14m with 52.30, 55.20, and 60.15%, respectively. Reputedly, the most satisfactory values found for ICLF-14 in March, and for ICLF-22m in September and November are associated to crude protein content higher than the minimum required, i.e., 7% for ruminants (NRC, 1996), can reflect in a good steers performance in grazing (MERTENS, 1994MERTENS, D.R. Regulation of forage intake. In: FAHEY, G.C.Jr.; COLLINS, M.; MERTENS, D.R. (Eds). Forage quality evaluation and utilization. Nebraska: American Society of Agronomy, Crop Science of America; Soil Science of America, 1994. 988p.).

Quintino et al. (2013QUINTINO, A.C.; ABREU, J.G.; ALMEIDA, R.G.; MACEDO, M.C.M.; CABRAL, L.S.; GALATI, R.L. Production and nutritive value of piatã grass and hybrid sorghum at different cutting ages. Acta Scientiarum. Animal Sciences, v.35, p.243-249, 2013.), evaluating Piatãgrass production and nutritional value in different cutting ages in integrated systems, observed that the in vitro digestibility of organic matter was lower in rainy season (January), when the weather conditions favored pasture growth. The authors argue that this behavior may be related to competition between plants in the system, leading to increased leaf senescence and stalk length, contributing to the reduction of forage digestibility, just as occurred in this experiment.

Euclides et al. (2009EUCLIDES, V.P.B.; MACEDO, M.C.; VALLE, C.B.; DIFANTE, G.S.; BARBOSA, R.A.; CACERE, E.R. Forage nutritive value and animal production in Brachiaria brizantha pastures. Pesquisa Agropecuária Brasileira, v.44, p.98-106, 2009.) evaluating the nutritive value of Brachiaria brizantha, Marandu, Piatã, and Xaraés cultivars, in full sun, found average values of CP, IVDOM, and NDF in leaf blade and stem for Piatã-grass: 8.2%; 50.1%, and 73.0%, respectively. Different from the agroforestry systems evaluated in this study, it was observed that, due to the arboreal component, the grass composing the understory has a higher nutritional quality.

Evaluating ICL system, it was observed the average content of 5.96% of crude protein in stem and sheath, and only ICLF-14m stood out in November and March, with the highest average of the systems, approximately 10.1%.

The lower NDF content of stem and sheath were observed in ICLF-22m and 14m, in November. However, it was observed that ICLF-22m have not presented significant difference when compared to ICL, in September and November.

ICL and ICLF-22m showed the lowest average content of 51.1%, of IVDOM, of stem and sheath in March; ICLF-14m showed an average of approximately 60.4% in November and March.

In general, the crude protein content and in vitro digestibility of organic matter found in foliar blades were higher than those found in stem and sheath, except in neutral detergent fiber. Probably due to the higher lignified tissues rate of such fraction.

Santos et al. (2012SANTOS, M.S.; OLIVEIRA, M.E.; RODRIGUES, M.M. VELOSO FILHO, E.S.; ARAUJO NETO, J.C. Structure and nutritional value of pasture grasses of Tanzania and Marandu at 22 and 36 days of regrowth for sheep. Revista Brasileira de Saúde e Produção Animal [online], v.13, p.35-46, 2012.) and Simoni et al. (2014) consider that the nutritive value of tropical grasses reduces insofar as occur the increase of senescent material quantity present in the pasture when the plant get closer to flowering stage, with higher involvement of stems in relation to leaves on biomass total composition, resulting in the decrease of crude protein content and digestibility, and increase of neutral and acid detergent fiber content.

Analyzing the delimited points in transects (A, B, C, D, and E), Table 4, it was observed that the lowest dry matter value of total forage in ICL was found in C, and there was no significant difference among other sampling points. Within ICLF-14m, C showed the highest dry matter production of the total forage, 730 kg ha^-1, whereas sampling points near the trees, represented by A and E, showed the lower biomass production, an average of 510 kg ha^-1. Although ICLF-22m showed similar behavior, it presented higher values for C point (1,640 kg ha^{- 1}), and lower values for points A and E (average 1,141 kg ha^-1). The PAR probably influenced to obtain the lowest values in these sampling points.

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Table 4
Total forage dry matter (TFDM), leaf blade dry matter (LDM), soil coverage (SC), photosynthetically active radiation (PAR), according to sampling location in three integrated systems

The ICLF-14m presented lower production of LDM at all analyzed point. ICLF-22m showed an average of 542 kg ha^-1 in B, C and D points.

According to Leonel et al. (2009LEONEL, F.P.; PEREIRA, F.C.; COSTA, M.G.; JUNIOR MARCO, P.; LARA, L.A.; QUEIROS, A.C. Productive performance and nutritional characteristics of signal grass intercropped with corn. Revista Brasileira de Zootecnia, v.28, p.177-189, 2009.) the low incidence of light in canopy in C4 grasses, decrease the forage dry matter production, since it requires higher quantity of light energy for assimilates production in order to perform photosynthesis.

ICL showed not significant difference for soil coverage variable, and with regard to sampling points, it showed a higher percentage of soil covered, an average of 76.6%. Within ICLF-22m, C point showed the highest soil coverage. This is probably due to sampling point position be more central between trees rows, favoring the sunlight capture.

According to Gobbi et al. (2011GOBBI, K.F.; GARCIA, R.; VENTRELLA, M.C.; GARCEZ NETO, A.F.; ROCHA, G.C. Specific leaf area and quantitative leaf anatomy of signalgrass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.40, p.1436-1444, 2011.) plants create acclimatization mechanisms in response to shading, trying to attenuate light allowing their survival.

PAR was influenced by sampling location in ICLF-22m, the highest PAR were observed in B, C and D points, showing an average of approximately 1,023 μmol m^-2 s^-1. However, this system does not differ significantly from values presented in ICL and ICLF- 14m, on B, C and D points. Possibly, the intermediate region between trees rows may have contributed to the results because of the higher solar incidence.

According to Oliveira et al. (2007OLIVEIRA, T.K.; MACEDO, R.L.G.; VENTURIN, N.; BOTELHO, S.A.; HIGASHIKAWA, E.M.; MAGALHÃES, W.M. Solar radiation in understory of agrosylvopastoral system with eucalypt on different spacings. Cerne, v.13, p.40-50, 2007.b), solar radiation incidence depends on the distribution of trees, where higher light transmission levels is found in arrangements with higher spacing between lines and rows of the trees, which was observed in this study.

Thumbnail

Table 5
Crude protein level (CP) of the foliar blade, stem and sheath of Piatã-grass, according to the sampling location, in three integrated systems

Sampling location did not influence the crude protein content of leaf blades within ICL. They were higher in ICLF-14m, in E, with 15% of CP, and in ICLF-22m, in A and E with an average of 12.57%. ICLF-22m showed the lower crude protein contents in B, C and D, with 10.8% of CP. Possibly, the lowest CP contents are associated with the higher intensity of light on Piatãgrass, increasing the structural compound and increasing the cellular contents.

According to Soares et al. (2009SOARES, A.B.; SARTOR, L.R.; ADAMI, P.F.; VARELLA, A.C.; FONSECA, L.; MEZZALIRA, J.C. Influence of luminosity on the behavior of eleven perennial summer forage species. Revista Brasileira de Zootecnia, v.38, p.443-451, 2009.) the photosynthetic radiation increment on forage is influenced by increasing the spacing between trees, which reduces the percentage of crude protein.

With regard to crude protein present in stem and sheath, the highest content was found in ICLF-22m, in A and E, 7.51%. In ICLF-14m, B and E points showed an average of 14.69% of CP.

Researcher as Paciullo et al. (2011PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011., 2007PACIULLO, DSC.; CARVALHO, C.A.B.; AROEIRA, L.J.M.; MORENZ, M.J.F.; LOPES, F.C.F.; ROSSIELLO, R.O.P. Morphophysiology and nutritive value of signalgrass under natural shading and full sunlight. Pesquisa Agropecuária Brasileira, v.42, p.573-579, 2007.) and Soares et al. (2009SOARES, A.B.; SARTOR, L.R.; ADAMI, P.F.; VARELLA, A.C.; FONSECA, L.; MEZZALIRA, J.C. Influence of luminosity on the behavior of eleven perennial summer forage species. Revista Brasileira de Zootecnia, v.38, p.443-451, 2009.) reported that the highest contents of crude protein in pasture, in natural shading conditions, can be associated to trees presence favoring the increase of organic matter, and consequently, increasing the nitrogen cycling.

Integrated crop-livestock-forest system spaced 22 m, stands out with higher crude protein values and in vitro digestibility of organic matter.

The lower tree density provides marginal improvements in nutritional parameters of the Piatã grass in relation to the systems with greater density of trees, but it stands out in relation to the production of biomass.

REFERENCES

ALMEIDA, R.G.; BARBOSA, R.A.; ZIMMER. A.H; KICHEL, AN. Forrageiras em sistemas de produção de bovinos em integração. In: BUNGENSTAB, D.J. Sistemas de integração lavoura-pecuária-floresta: a produção sustentável. 2.ed. Brasília, DF: EMBRAPA, 2012. p.88-94.
ARAUJO, R.P.; ALMEIDA, J.C.C.; ARAÚJO, S.A.C.; RIBEIRO, E.T.; PÁDUA, F.T.; CARVALHO, C.A.B.; BONAPARTE, T.P.; DEMINICIS, B.B.; LISTA, F.N. production and chemical composition of brachiaria decumbens cv. Basilisk in silvipastoral system under different spacing with eucalyptus urophylla s.t. blake. Revista Brasileira de Agropecuária Sustentável, v.3, p.90-98, 2013.
BARRO, R.S.; SAIBRO, J.C.; MEDEIROS, R.B.; SILVA, J.L.S; VARELLA, A.C. Forage yield and nutritive value of cool-season annual forage grasses shaded by Pinus elliottii trees and at full-sun. Revista Brasileira de Zootecnia, v.37, p.1721-1727, 2008.
DIM, V.P.; ALEXANDRINO, E.; SANTOS, A.C.; MENDES, R.S.; SILVA, D.P. Agronomic characteristics, structural and chemical characteristics of grass in Piata stocking with intermittent rest periods vary depending on the sward height. Revista Brasileira de Saúde e Produção Animal [online], v.16, n.1, p.10-22, 2015.
EUCLIDES, V.P.B.; MACEDO, M.C.; VALLE, C.B.; DIFANTE, G.S.; BARBOSA, R.A.; CACERE, E.R. Forage nutritive value and animal production in Brachiaria brizantha pastures. Pesquisa Agropecuária Brasileira, v.44, p.98-106, 2009.
FONTANA, D.C.; ALVES, G.M.A.; ROBERTI, O.L.L.M.; GERHARDT, A. Estimation of the absorbed photosynthetically active radiation by the soybean crop through modis sensor data. Bragantia, v.71, p.563-571, 2012.
GALHARTE, C.A.; CRESTANA, S. The assessment of the environmental impact of agriculture-animal husbandry integration: Environmental conservation aspect in ‘Cerrado’. Revista Brasileira de Engenharia Agrícola e Ambiental, v.14, p.1202-1209, 2010.
GARCIA, R.; TONNUCCI, R.G.; GOBBI, K.F. Silvipastoris: uma integração pasto, árvore e animal. In: OLIVEIRA NETO, S.N. VALE, A.B.; NACIF, A.P.; VILAR, M.B.; ASSIS, J.B. (Eds). Sistema agrossilvipastoril: integração lavoura, pecuária e floresta. Viçosa, MG: Sociedade de Investigação Florestal, 2010. 189.p
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GOBBI, K.F.; GARCIA, R.; VENTRELLA, M.C.; GARCEZ NETO, A.F.; ROCHA, G.C. Specific leaf area and quantitative leaf anatomy of signalgrass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.40, p.1436-1444, 2011.
GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Nutritive value of signalgrass and forage peanut submitted to shading. Archivos de Zootecnia, v. 59, p. 379-390, 2010.
KÖPPEN W. Climatologia: con um estúdio de lós climas de la tierra México: Fondo de Cultura Econômica, 1948. p.479.
LEONEL, F.P.; PEREIRA, F.C.; COSTA, M.G.; JUNIOR MARCO, P.; LARA, L.A.; QUEIROS, A.C. Productive performance and nutritional characteristics of signal grass intercropped with corn. Revista Brasileira de Zootecnia, v.28, p.177-189, 2009.
MARTEN, G.C.; SHENK, J.S.; BARTON II, F.E. Near infrared reflectance spectroscopy (NIRS): analysis quality. Washington: USDA, 1985. p.110. (Agriculture handbook, 643).
MARTINS, J.R.; ALVARENGA, A.A.; CASTRO, E.M.; SILVA, A.P.; ALVES, E. Pigments content and Alfavaca-cravo chloroplast structure cultivate under colored nets. Ciência Rural, v.40, p.64-69, 2010.
MARTUSCELLO, J.A.; JANK, L.; GONTIJO NETO, M.M.; LAURA, V.A.; CUNHA, D.N.F.V. Genus Brachiaria grass yields under different shade levels. Revista Brasileira de Zootecnia, v.38, p.1183-1190, 2009.
MERTENS, D.R. Regulation of forage intake. In: FAHEY, G.C.Jr.; COLLINS, M.; MERTENS, D.R. (Eds). Forage quality evaluation and utilization Nebraska: American Society of Agronomy, Crop Science of America; Soil Science of America, 1994. 988p.
NATIONAL RESEARCH COUNCIL - NRC. Nutrients requirements of beef cattle 7.ed. Washington, D.C.: National Academic Press, 1996. 242p.
OLIVEIRA, T.K.; MACEDO, R.L.G.; VENTURIN, N.; BOTELHO, S.A.; HIGASHIKAWA, E.M.; MAGALHÃES, W.M. Solar radiation in understory of agrosylvopastoral system with eucalypt on different spacings. Cerne, v.13, p.40-50, 2007.
OLIVEIRA, C.C.; VILLELA, D.S.; ALMEIDA, R.G.; ALVES, F.V.; NETO BEHLING, A.; MARTINS, P.G.M.A. Performance of Nellore heifers, forage mass, and structural and nutritional characteristics of Brachiaria brizantha grass in integrated production systems. Tropical Animal Health and Production, v.46, p.167-172, 2014.
PACIULLO, DSC.; CARVALHO, C.A.B.; AROEIRA, L.J.M.; MORENZ, M.J.F.; LOPES, F.C.F.; ROSSIELLO, R.O.P. Morphophysiology and nutritive value of signalgrass under natural shading and full sunlight. Pesquisa Agropecuária Brasileira, v.42, p.573-579, 2007.
PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011.
PERI, P.L.; LUCAS, R.J.; MOOT, D.J. Dry matter production, morphology and nutritive value of Dactylis glomerata growing under different light regimes. Agroforestry Systems, v.70, p.63-79, 2007.
QUINTINO, A.C.; ABREU, J.G.; ALMEIDA, R.G.; MACEDO, M.C.M.; CABRAL, L.S.; GALATI, R.L. Production and nutritive value of piatã grass and hybrid sorghum at different cutting ages. Acta Scientiarum. Animal Sciences, v.35, p.243-249, 2013.
SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de; OLIVEIRA, J.B. de; COELHO, M.R.; LUMBRERAS, J.F.; CUNHA, T.J.F. (Ed.). Sistema brasileiro de classificação de solos 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306p.
SANTOS, M.S.; OLIVEIRA, M.E.; RODRIGUES, M.M. VELOSO FILHO, E.S.; ARAUJO NETO, J.C. Structure and nutritional value of pasture grasses of Tanzania and Marandu at 22 and 36 days of regrowth for sheep. Revista Brasileira de Saúde e Produção Animal [online], v.13, p.35-46, 2012.
STATISTICAL ANALYSIS SISTEM. SAS® User's Guide: Statistics. Version 8.0. Cary, NC, USA: SAS Institute Inc., 2002.
SBRISSIA, A.F.; SILVA, S.C. da. Tiller size/density compensation in Marandu palisadegrass swards. Revista Brasileira de Zootecnia, v.37, p.35-47, 2008.
SILVA, S.C da.; BUENO, A.A.O.; CARNEVALLI, R.A.; UBELE, M.C.; BUENO, F.O.; HODGSON, J.; MATTHEW, C.; ARNOLD, G.C.; MORAIS, J.P.G. Swards structural charateristic and herbage accumulation of Panicum maxinum cv. Mombaça subjected to rotational stocking managements. Scientia Agrícola, v.66, p.8-19, 2009.
SIMIONI, T.A.; HOFFMANN, A.; GOMES JUNIOR, F.; MOUSQUER, C.J.; TEIXEIRA, U.H.G.; FERNANDES, G.A.; BOTINI, L.A.; PAULA, D.C. Senescence, removal, transport of nutrients and nutritional value in tropical grasses. Publicações em Medicina Veterinária e Zootecnia, v.8, p.1551-1697, 2014.
SOARES, A.B.; SARTOR, L.R.; ADAMI, P.F.; VARELLA, A.C.; FONSECA, L.; MEZZALIRA, J.C. Influence of luminosity on the behavior of eleven perennial summer forage species. Revista Brasileira de Zootecnia, v.38, p.443-451, 2009.
SOUSA, L.F.; MAURÍCIO, R.M.; MOREIRA, G.R.; GONÇALVES, L.C.; BORGES, I.; PEREIRA, L.G.R. Nutritional evaluation of Braquiarão grass in association with Aroeira trees in a silvopastoral system. Agroforestry Systems, v.79, n.2, p.189-199, 2010.
MANNETJE, L.T. Measurement of grassland vegetation and animal production Aberystwyth: CAB, 1978. 260 p. (CAB Bulettin, 52).
VALLE, C.B.; EUCLIDES, V.P.B.; VALÉRIO, J.R.; MACEDO, M.C.M.; FERNANDES, CD.; DIAS FILHO, M.B. Brachiaria brizantha cv. Piatã: uma forrageira para diversificação de pastagens tropicais. Seed News, v.11, n.2, p.28-30, 2007.

Publication Dates

Publication in this collection
Apr-Jun 2018

History

Received
31 Oct 2017
Accepted
21 May 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALMEIDA, R.G.; BARBOSA, R.A.; ZIMMER. A.H; KICHEL, AN. Forrageiras em sistemas de produção de bovinos em integração. In: BUNGENSTAB, D.J. Sistemas de integração lavoura-pecuária-floresta: a produção sustentável. 2.ed. Brasília, DF: EMBRAPA, 2012. p.88-94.

[2] ARAUJO, R.P.; ALMEIDA, J.C.C.; ARAÚJO, S.A.C.; RIBEIRO, E.T.; PÁDUA, F.T.; CARVALHO, C.A.B.; BONAPARTE, T.P.; DEMINICIS, B.B.; LISTA, F.N. production and chemical composition of brachiaria decumbens cv. Basilisk in silvipastoral system under different spacing with eucalyptus urophylla s.t. blake. Revista Brasileira de Agropecuária Sustentável, v.3, p.90-98, 2013.

[3] BARRO, R.S.; SAIBRO, J.C.; MEDEIROS, R.B.; SILVA, J.L.S; VARELLA, A.C. Forage yield and nutritive value of cool-season annual forage grasses shaded by Pinus elliottii trees and at full-sun. Revista Brasileira de Zootecnia, v.37, p.1721-1727, 2008.

[4] DIM, V.P.; ALEXANDRINO, E.; SANTOS, A.C.; MENDES, R.S.; SILVA, D.P. Agronomic characteristics, structural and chemical characteristics of grass in Piata stocking with intermittent rest periods vary depending on the sward height. Revista Brasileira de Saúde e Produção Animal [online], v.16, n.1, p.10-22, 2015.

[5] EUCLIDES, V.P.B.; MACEDO, M.C.; VALLE, C.B.; DIFANTE, G.S.; BARBOSA, R.A.; CACERE, E.R. Forage nutritive value and animal production in Brachiaria brizantha pastures. Pesquisa Agropecuária Brasileira, v.44, p.98-106, 2009.

[6] FONTANA, D.C.; ALVES, G.M.A.; ROBERTI, O.L.L.M.; GERHARDT, A. Estimation of the absorbed photosynthetically active radiation by the soybean crop through modis sensor data. Bragantia, v.71, p.563-571, 2012.

[7] GALHARTE, C.A.; CRESTANA, S. The assessment of the environmental impact of agriculture-animal husbandry integration: Environmental conservation aspect in ‘Cerrado’. Revista Brasileira de Engenharia Agrícola e Ambiental, v.14, p.1202-1209, 2010.

[8] GARCIA, R.; TONNUCCI, R.G.; GOBBI, K.F. Silvipastoris: uma integração pasto, árvore e animal. In: OLIVEIRA NETO, S.N. VALE, A.B.; NACIF, A.P.; VILAR, M.B.; ASSIS, J.B. (Eds). Sistema agrossilvipastoril: integração lavoura, pecuária e floresta. Viçosa, MG: Sociedade de Investigação Florestal, 2010. 189.p

[9] GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.G.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Morphological and structural characteristics and productivity of Brachiaria grass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.38, p.1645-1654, 2009.

[10] GOBBI, K.F.; GARCIA, R.; VENTRELLA, M.C.; GARCEZ NETO, A.F.; ROCHA, G.C. Specific leaf area and quantitative leaf anatomy of signalgrass and forage peanut submitted to shading. Revista Brasileira de Zootecnia, v.40, p.1436-1444, 2011.

[11] GOBBI, K.F.; GARCIA, R.; GARCEZ NETO, A.F.; PEREIRA, O.G.; VENTRELLA, M.C.; ROCHA, G.C. Nutritive value of signalgrass and forage peanut submitted to shading. Archivos de Zootecnia, v. 59, p. 379-390, 2010.

[12] KÖPPEN W. Climatologia: con um estúdio de lós climas de la tierra México: Fondo de Cultura Econômica, 1948. p.479.

[13] LEONEL, F.P.; PEREIRA, F.C.; COSTA, M.G.; JUNIOR MARCO, P.; LARA, L.A.; QUEIROS, A.C. Productive performance and nutritional characteristics of signal grass intercropped with corn. Revista Brasileira de Zootecnia, v.28, p.177-189, 2009.

[14] MARTEN, G.C.; SHENK, J.S.; BARTON II, F.E. Near infrared reflectance spectroscopy (NIRS): analysis quality. Washington: USDA, 1985. p.110. (Agriculture handbook, 643).

[15] MARTINS, J.R.; ALVARENGA, A.A.; CASTRO, E.M.; SILVA, A.P.; ALVES, E. Pigments content and Alfavaca-cravo chloroplast structure cultivate under colored nets. Ciência Rural, v.40, p.64-69, 2010.

[16] MARTUSCELLO, J.A.; JANK, L.; GONTIJO NETO, M.M.; LAURA, V.A.; CUNHA, D.N.F.V. Genus Brachiaria grass yields under different shade levels. Revista Brasileira de Zootecnia, v.38, p.1183-1190, 2009.

[17] MERTENS, D.R. Regulation of forage intake. In: FAHEY, G.C.Jr.; COLLINS, M.; MERTENS, D.R. (Eds). Forage quality evaluation and utilization Nebraska: American Society of Agronomy, Crop Science of America; Soil Science of America, 1994. 988p.

[18] NATIONAL RESEARCH COUNCIL - NRC. Nutrients requirements of beef cattle 7.ed. Washington, D.C.: National Academic Press, 1996. 242p.

[19] OLIVEIRA, T.K.; MACEDO, R.L.G.; VENTURIN, N.; BOTELHO, S.A.; HIGASHIKAWA, E.M.; MAGALHÃES, W.M. Solar radiation in understory of agrosylvopastoral system with eucalypt on different spacings. Cerne, v.13, p.40-50, 2007.

[20] OLIVEIRA, C.C.; VILLELA, D.S.; ALMEIDA, R.G.; ALVES, F.V.; NETO BEHLING, A.; MARTINS, P.G.M.A. Performance of Nellore heifers, forage mass, and structural and nutritional characteristics of Brachiaria brizantha grass in integrated production systems. Tropical Animal Health and Production, v.46, p.167-172, 2014.

[21] PACIULLO, DSC.; CARVALHO, C.A.B.; AROEIRA, L.J.M.; MORENZ, M.J.F.; LOPES, F.C.F.; ROSSIELLO, R.O.P. Morphophysiology and nutritive value of signalgrass under natural shading and full sunlight. Pesquisa Agropecuária Brasileira, v.42, p.573-579, 2007.

[22] PACIULLO, D.S.C.; GOMIDE, CAM.; DE CASTRO, R.T.; FERNANDES, P.B.; MÜLLER, M.D.; PIRES, M.F.; FERNANDES, E.N.; XAVIER, D.F. Productive and nutritional traits of pasture in an agrosilvopastoral system, according to the distance from trees. Pesquisa Agropecuária Brasileira, v.46, p. 1176-1183, 2011.

[23] PERI, P.L.; LUCAS, R.J.; MOOT, D.J. Dry matter production, morphology and nutritive value of Dactylis glomerata growing under different light regimes. Agroforestry Systems, v.70, p.63-79, 2007.

[24] QUINTINO, A.C.; ABREU, J.G.; ALMEIDA, R.G.; MACEDO, M.C.M.; CABRAL, L.S.; GALATI, R.L. Production and nutritive value of piatã grass and hybrid sorghum at different cutting ages. Acta Scientiarum. Animal Sciences, v.35, p.243-249, 2013.

[25] SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de; OLIVEIRA, J.B. de; COELHO, M.R.; LUMBRERAS, J.F.; CUNHA, T.J.F. (Ed.). Sistema brasileiro de classificação de solos 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306p.

[26] SANTOS, M.S.; OLIVEIRA, M.E.; RODRIGUES, M.M. VELOSO FILHO, E.S.; ARAUJO NETO, J.C. Structure and nutritional value of pasture grasses of Tanzania and Marandu at 22 and 36 days of regrowth for sheep. Revista Brasileira de Saúde e Produção Animal [online], v.13, p.35-46, 2012.

[27] STATISTICAL ANALYSIS SISTEM. SAS® User's Guide: Statistics. Version 8.0. Cary, NC, USA: SAS Institute Inc., 2002.

[28] SBRISSIA, A.F.; SILVA, S.C. da. Tiller size/density compensation in Marandu palisadegrass swards. Revista Brasileira de Zootecnia, v.37, p.35-47, 2008.

[29] SILVA, S.C da.; BUENO, A.A.O.; CARNEVALLI, R.A.; UBELE, M.C.; BUENO, F.O.; HODGSON, J.; MATTHEW, C.; ARNOLD, G.C.; MORAIS, J.P.G. Swards structural charateristic and herbage accumulation of Panicum maxinum cv. Mombaça subjected to rotational stocking managements. Scientia Agrícola, v.66, p.8-19, 2009.

[30] SIMIONI, T.A.; HOFFMANN, A.; GOMES JUNIOR, F.; MOUSQUER, C.J.; TEIXEIRA, U.H.G.; FERNANDES, G.A.; BOTINI, L.A.; PAULA, D.C. Senescence, removal, transport of nutrients and nutritional value in tropical grasses. Publicações em Medicina Veterinária e Zootecnia, v.8, p.1551-1697, 2014.

[31] SOARES, A.B.; SARTOR, L.R.; ADAMI, P.F.; VARELLA, A.C.; FONSECA, L.; MEZZALIRA, J.C. Influence of luminosity on the behavior of eleven perennial summer forage species. Revista Brasileira de Zootecnia, v.38, p.443-451, 2009.

[32] SOUSA, L.F.; MAURÍCIO, R.M.; MOREIRA, G.R.; GONÇALVES, L.C.; BORGES, I.; PEREIRA, L.G.R. Nutritional evaluation of Braquiarão grass in association with Aroeira trees in a silvopastoral system. Agroforestry Systems, v.79, n.2, p.189-199, 2010.

[33] MANNETJE, L.T. Measurement of grassland vegetation and animal production Aberystwyth: CAB, 1978. 260 p. (CAB Bulettin, 52).

[34] VALLE, C.B.; EUCLIDES, V.P.B.; VALÉRIO, J.R.; MACEDO, M.C.M.; FERNANDES, CD.; DIAS FILHO, M.B. Brachiaria brizantha cv. Piatã: uma forrageira para diversificação de pastagens tropicais. Seed News, v.11, n.2, p.28-30, 2007.

Month	Tmax (°C)	Tmin (°C)	RHmin (%)	Precipitation (mm)	Global radiation (μmol m^-2 s^-1)
September	32.3	20.3	22	66.0	163.5
November	30.8	19.9	32	217.8	163.7
January	32.2	21.2	44	263.6	187.8
March	31.1	21.1	49	164.4	181.8

System	Period of the year
System	September (2014)	November (2014)	January (2015)	March\| (2015)	SEM¹
TFDM (kg ha^-1)
ICL	2.234^aB	1.726^aC	2.007^aB	2.867^aA	67.76
ILCF_14m	498^cB	464^bB	637^cB	1.024^cA	52.01
ICLF _22m	1.156^bB	839^bC	1.230^bB	2.172^bA	78.11
LDM (kg ha^-1)
ICL	451^aC	520^aC	960^aB	1.091^aA	36.64
ILCF_14m	64^bC	135^bC	237^cB	511^cA	27.22
ICLF _22m	167^bC	266^bC	678^bB	834^bA	38.46
L/S ratio
ICL	1,95^aB	2,60^aA	2,30^aA	1,10^aC	0.093
ILCF_14m	0,35^cB	1,45^bA	1,20^bA	1,55^aA	0.071
ICLF _22m	1,25^bC	2,50^aA	1,60^bB	1,00^aC	0.119
CS (%)
ICL	77^aB	73^aB	83^aA	73^aB	0.79
ILCF_14m	37^bB	27^cC	41^bB	46^bA	1.77
ICLF _22m	50^bB	50^bB	75^aA	51^bB	1.63
PAR (μmol m^-2 s^-1)
ICL	858^aB	1.691^aA	553^aC	1.527^aA	66.02
ILCF_14m	875^aA	657^bB	158^bC	970^bA	69.22
ICLF _22m	913^aB	741^bB	105^bC	1.247^abA	76.62
Pasture height (cm)
ICL	32^aB	30^abB	42^bA	43^aA	0.86
ILCF_14m	26^aB	24^bB	25^cB	49^aA	1.56
ICLF _22m	31^aC	34^aC	56^aA	47^aB	1.41

System	Period of the year
System	September	November	January	March	SEM¹
Leaf Blade
CP (%)
ICL	8,55^cB	10,10^cA	7,90^bB	10,30^cA	0.16
ICLF_22m	11,45^bA	12,40^bA	9,80^bB	13,25^bA	0.32
ICLF_14m	13,30^aC	14,45^aB	11,50^aD	16,65^aA	0.27
NDF (%)
ICL	70,95^aB	70,15^aB	76,75^aA	71,20^aB	0.37
ICLF_22m	69,95^aB	68,65^abB	75,50^aA	69,10^abB	0.45
ICLF_14m	65,25^bC	67,40^bB	72,25^bA	67,95^bB	0.47
IVDOM (%)
ICL	58,45^bB	62,70^bA	52,30^bC	58,85^cB	0.53
ICLF_22m	66,40^aA	67,20^abA	55,20^bB	64,70^bA	0.83
ICLF_14m	68,30^aB	69,95^aB	60,15^aC	72,30^aA	0.86
Stem + sheath
CP (%)
ICL	5,90^aA	6,65^cA	5,40^bA	5,90^bA	0.10
ICLF_22m	6,05^aB	8,60^bA	5,80^bB	6,60^bB	0.27
ICLF_14m	6,25^aC	10,35^aA	7,75^aB	9,75^aA	0.25
NDF (%)
ICL	75,50^aB	75,00^aB	79,70^aA	78,60^aA	0.35
ICLF_22m	77,50^aA	73,45^abB	78,90^aA	78,90^aA	0.40
ICLF_14m	76,35^aA	71,40^bB	76,15^bA	74,55^bA	0.39
IVDOM (%)
ICL	51,65^aA	54,65^bA	52,70^aA	51,40^bA	0.44
ICLF_22m	51,60^aB	58,80^aA	53,00^aB	50,80^bB	0.85
ICLF_14m	48,05^aC	61,30^aA	55,60^aB	59,40^aA	0.69

System	Sampling location
System	A	B	C	D	E	SEM¹
THDM (kg ha^-1)
ILC	2.293^aA	2.221^aA	2.004^aB	2.199^aA	2.324^aA	67.76
ICLF _14m	471^cB	794^cA	730^Ab	734^cA	550^cB	52.01
ICLF _22m	1.189^bC	1.433^bB	1.642^aA	1.390^bB	1.093^bC	78.11
LDM (kg ha^-1)
ILC	836^aA	763^aA	673^aB	770^aB	740^aB	36.64
I ICLF _14m	192^cA	269^cA	260^bA	274^cA	190^cA	27.22
ICLF _22m	416^bB	534^bA	569^aA	524^bA	388^bB	38.45
SC (%)
ILC	79^aA	76^aA	74^aA	75^aA	79^aA	0.79
ICLF _14m	35^bB	39^bA	42^bA	41^cA	33^Bc	1.77
ICLF _22m	48^bC	60^cB	64^aA	60^bB	49^bC	1.62
PAR (μmol m^-2 s^-1)
ILC	1.181^aA	1.226^aA	1.119^aA	1.081^aA	1.178^aA	66.02
ICLF _14m	729^bA	828^bA	751^bA	693^bA	325^bB	69.22
ICLF _22m	563^bB	991^abA	1.094^abA	985^abA	126^bC	76.61

System	Sampling location
System	A	B	C	D	E	SEM¹
Leaf Blade
CP (%)
ICL	9,13^bA	9,00^cA	9,25^bA	9,13^cA	9,56^cA	0.16
ILCF_14m	13,88^aB	14,38^aA	13,63^aB	13,00^aB	15,00^aA	0.32
ILCF_22m	12,75^aA	10,81^bB	10,38^bB	11,06^bB	12,38^bA	0.27
Stem + sheath
CP (%)
ICL	6,13^bA	5,94^bA	6,13 ^bA	5,69^bA	5,94^bA	0.10
ILCF_14m	8,50^aA	8,31^aA	8,44^aA	9,19^aA	8,19^aA	0.27
I ILCF_22m	8,13^aA	6,75^bB	6,06^bB	6,00^bB	6,88^abA	0.25

Brasil

Brasil

Productive and nutritional characteristics of Piatã-grass in integrated systems

Características produtivas e nutricionais do capim-Piatã em sistemas integrado

SUMMARY

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

REFERENCES

Publication Dates

History